Semester V – WEEK 1 HEMATOLOGY MODULE PHARMACOLOGY IRON,B12 TREATMENT LEARNING OBJECTIVES: • • • • • • • Sites of action of erythropoietin. Explain the approved indications for treatment of anemia by erythropoietin, iron, folic By the end of this lecture the student should be able to Describe the causes of different anemias. Explain the type of anemia expected as a result of deficiencies of iron, erythropoietin, Vitamin B12 and folic acid. Describe the primary acid and Vitamin B12. Describe the absorption of iron by the intestines. Explain the treatment for iron toxicity or overdose. DRUG LIST: Erythropoietin, darbopoietin, thrombopoietin, oprelvekin (IL11), filgrastim (G-CSF), iron preparations (ferrous sulfate, iron dextran, iron sucrose, ferric gluconate), iron overdose preparations (deferoxamine, deferasirox), folic acid, Vitamin B12 ANEMIA: • Definition Anemia; from Ancient Greek word,meaning lack of blood, is a decrease in number of red blood cells (RBCs) or less than the normal quantity of hemoglobin in the blood,or decreased oxygen-binding ability BLOOD PARAMETERS • • • • • Hemoglobin concentration (Hg) • F: 7,2 –10; M: 7,8-11,3 mmol Fe/l (12-18 g/dl) Erythrocytes count (RBC) • F: 4-5,5; M: 4,5-6 x1012/l (4-6 x106 /l) Hematocrit (Hct) • F: 37-47; M: 40-54; (37-54%) Platelet count (Plt) • 150 – 450 x 103/l (150-450 x 109/l) Leukocytes count (WBC) • 4-10 x 109/l (4-10 x 103/ l) ERYTHROCYTES PARAMETERS – Mean corpuscular volume (MCV) – N: 80-100 fl – Mean corpuscular hemoglobin (MCH) – N: 27-34 pg – Mean corpuscular hemoglobin concentration (MCHC) – N: 310 – 370 g/lRBC (31-37 g/dl) CAUSES OF ANEMIA • A: Blood Loss 1:Acute eg: trauma 2:Chronic eg: GIT lesions • B: Inadequate RBCs Production 1:Deficiency of essencial factors a:Iron deficiency anemia b:Intrinsic factor deficiency c:Vit.B12 or Folic acid deficiency 2:Endocrine deficiency e.g.: dec erythropoietin production 3:Bone marrow invasion e.g.: a: leukemia b: secondary carcinoma 4:Stem cells failure e.g.: aplastic anemia 5:Drugs e.g.: cholramphenicol thiouracil C: Increased RBCs Desrtuction 1: Intra-erythrocytic defects a:Hereditary spherocytosis b:Thalassemia 2: Extra-erythrocytic abnormalities a: Erythroblastosis fetalis b: Transfusion reactions c: Malaria BASIC PHARMACOLOGY • • • • Most common cause of chronic anemia Iron forms the nucleus of the iron–porphyrin heme ring Heme together with globin forms hemoglobin Hemoglobin reversibly binds with oxygen and carry it from lungs to other tissues. PHARMACOKINETICS MECHANISM OF IRON ABSORPTION • Absorption: Daily requirement 10-15mg 0.5 -1 mg daily absorbs Site: duodenum and proximal jejunum Absorption increases: low iron stores or increase iron requirements Mensturating women 1-2 mg/d Pregnant women 3-4 mg/d IRON CROSSES THE INTESTINAL MUCOSAL CELL BY 1:active transport of ferrous iron 2:absorption of iron complexed with heme DMT1 divalent metal transporter, transports ferrous iron across the luminal membrane. Dietary iron in the form of heme and the ferrous ion (Fe2+)are taken up by specialized transporters ferroreductase in intestinal epithelial cells and oxidized in the mucosal cell to the ferric(Fe3+)form by ferroxidase. TRANSPORT • • • Iron bound to transferrin to transport in the plasma Ferric iron is released ,reduce ferrous iron and transported by DMT1 into the cell . Transferrin-transferrin complex is recycled to the plasma, here trasfferin dissociate and return to plasma STORAGE: • Stored in the mucosa (bound to ferritin), • Carried elsewhere in the body (bound to transferrin) • Excess iron stored in the protein –bound form in macrophages and hepatocytes • • Gross overload ,in parenchymal cells of the skin, heart and other organs. Apoferritin level is regulated by free iron levels ELIMINATION • • • • • No mechanism for excretion Small amounts are lost in the feces no more than 1mg per day Traces excreted in bile. sweat and urine M.O.A Fe combines with protoporphyrin IX & forms heme→4-heme combine with polypeptide (gobin) to form hemoglobin (α or β) IRON DEFICIENCY ANEMIA • GENERAL SYMPTOMS: – FATIGABILITY – DIZZENES – HEADACHE – IRRITABILITY – ROARING – PALPITATION THERAPEUTIC USES OF IRON • Iron Deficient Anemia • Pregnancy • Premature Babies • • • • • B l ood l os s Hookworn infestation Malabsorption Syndrome GI Bleeding due to: • Ulcers • Aspirin • Excess consumption of coffee Preparation of Iron i)Oral Iron ii) Parenteral Iron Oral Iron • Ferrous Sulphate • Ferrous Gluconate • Ferrous Fumarate • Dose: 200 - 400mg daily and continue for 3-6 months in iron deficiency anaemia Adverse Effects: nausea, epigastric discomfort, abd.cramps, constipation and diarrhea • Parenteral Iron INDICATION FOR USE in pts unable to tolerate or absorb oral iron in pts with chronic blood loss. PREPARATION AVAILABLE • • • • • • • Iron – Dextran. (imferon) Sodium ferric gluconate complex Iron – Sucrose (Jectofer) Iron – Dextran. (imferon): complex of ferric oxyhydroxide and dextran 50 mg of elemental iron/ml of solution Deep I/M inj or I/V infusion. ADVERSE EFFECTS: Local pain & tissue staining Headache, giddiness, flushing Fever, Arthralgia, Backache Nausea, Vomiting Urticaria Rarely Anaphylaxis & death. • • • Sodium ferric gluconate complex and Iron – Sucrose (Jectofer Only given through I/V Hypersensitivity reaction is less than dextran. TOXICITY Acute Iron Toxicity • Symptoms: necrotizing gastroenteritis, abd pain, bloody diarrhoea followed by metabolic acidosis, dyspnea, coma & death Rx • i)Gastric Aspiration Gastric lavage, with carbonate solution to form insoluble Iron. ii) Deferoxamine - potent iron chelating compound iii) Supportive Therapy Chronic Iron Toxicity • Seen in pt with hemochromatosis, and who received many red cell transfusion • Lead to organ failure or death • Rx – Intermittent Phlebotomy – Oral iron chelator deferasirox FOLIC ACID • Essential for normal DNA synthesis PHARMACOKINETICS OF FOLIC ACID • Daily requirment 500-700 mcg • 50-200mcg daily absorbs • • • • • • • Pregnant women 300 400mcg Richest source:yeast, liver, kidney, green vegetables Store in liver and other tissues 5-20mg of folates Excreted in urine and stool and also destroy by catabolism Dietary folate Polyglutame of N5 –methyltetrahydrofolate After absorption hydrolyed by the enzyme alpha-1-glutamyl transferase Transported into the blood stream by active and passive transport and then distributed. FOLIC DEFICIENCY SEEN IN • Inadequate dietary intake of folates • Prolong cooking • In alcaholics & in pt with liver diseases • Pregnancy • Hemolytic Anemias • Malabsorption Syndrome • Occasionally associated with cancers, Leukemias., in certain skin disorders, in chronic debiliating disease • Pt. on Renal dialysis. • Drugs interferring folate absorption or metabolism e.g Phenytoin, Anti-convulsants, Oral contraceptives, Isoniazid & others. TREATMENT OF FOLIC ACID DEFICIENCY • • parentral administration rarely needed. Oral therapy Dose-1mg/d – continued until cause is corrected or removed. Folic Acid supplementation, in high risk pts. Clinical Toxicity of Vit B12 & Folic acid not usually seen. Vit B12 deficiency seen in • • Deficiency of intrinsic factor Defect in absorption of Vit B12 Pernicious Anemia Partial or total gastrectomy Diseases affecting distal ileum. Strict vegetarians TREATMENT Treatment of underlying disease Parenteral therapy with Inj Cyanocobalamin or hydroxocobalamin • Initial therapy 100 – 1000 µg – I/M daily or on alternate days for 1-2weeks Maintenance therapy 100 – 1000 µg – I/M- once a month For Pernicious Anemia 1000 µg Orally of vitamin B12/daily HEMATOPOIETIC GROWTH FACTORS Proteins that regulate the proliferation and differentiation of hematopoietic cells i.e. erythrocytes, platelets and leukocytes • • • • Erythropoietin Myeloid growth factors Megakaryocytic growth factors Erythropoietin • • Produced by the kidney Reduction in synthesis responsible for the anemia of renal failure. PHARMACOLOGICAL EFFECT Stimulates the production and release of red cells ,by activating the receptors on erythroid progenitors in the bone marrow. ERYTHROPOIETIN (T/U) • • • • • • Anemia of chronic renal disease Primary bone marrow disorders Anemia associated with malignancy & chemotherapy Anemia of chronic diseases HIV treatment Bone marrow transplantation Erythropoietin A/E Thrombosis and hypertension • Myeloid Growth Factors CHEMISTRY • G-CSF (granulocyte colony stimulating factor) • GM-CSF (granulocyte macrophage colony stimulating factor) Originally purified from cultured human cell lines 1: filgrastin (G-CSF) Produced in a bacterial expression system Non –glycosylated peptide of 175 amino acids M.W 18kDa 2: sargramostin (GM-CSF) produced in yeast expression system Glycosylated peptide of 127 amino acids 3 molecular species 15,500; 15,800; 15,900 Half life 2-7 hours PHARMACODYNAMICS Stimulate proliferation and differentiation by interacting with specific receptors found on myeloid progenitor cells Stimulate the production and function of neutrophils after cancer chemotherapy It activates the phagocytic activity of mature neutrophils and prolong their survival in the circulation G-CSF has remarkably ability to mobilize hematopoietic stem cells Helps in major advance in transplantation The use of peripheral blood stem cells(PBSCs) rather than bone marrow stem cells for transplantation • • GM-CSF acts together with interleukin-2 to stimulate T-cell proliferation locally active factor at site of inflammation. THERAPEUTIC USES • • • • 5. Congenital neutropenia Cyclic neutropenia Myelodysplasia Aplastic anemia stem cell transplantation. SIDE EFFECTS Fever Malaise Arthralgias Myalgias Capillary leak syndrome (peripheral edema and pleural or pericardial effusion) TOXICITY Bone pain. MEGAKARYOCYTE GROWTH FACTORS • Chemistry & Pharmacokinetics thrombopoietin and interleukin-11 are the key endogenous regulators of platelets production 1:Recombinant form of IL-11(OPRELVEKIN) was the first agent for the treatment of thrombocytopenia Interleukin-11 is 65-85kDa protein produced by fibroblast and stromal cells in the bone marrow Half life:7-8hours ROA: subcutaneously 2:Romiplostin Half life:3-4 days (inversely related to serum platelet count) ROA: subcutaneously 3:Eltrombopag new orally small molecule agonist at thrombopoietin receptor Use in idiopathic thrombocytopenia. PHARMACODYNAMICS • • • • • Stimulates the growth of multiple lymphoid and myeloid cell by acting on cytokine receptors Increases the number of peripheral platelets and neutrophils Therapeutic uses Secondary thrombocytopenia Idiopathic thrombocytopenia ADVERSE EFFECTS: fatigue Headache Dizziness Anemia Dysnea Atrial arraythmia REFERENCES: • BASIC AND CLINICAL PHARMACOLOGY,KATZUNG, 11th EDITION. _____________________________________________
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